[0001] The present invention relates to an automated experiment apparatus according to claim
1 and an automated experiment method of claim 12 using the same and, more specifically,
to an apparatus and method for putting a sample into a pressure vessel and automatically
performing a chemical and/or physical reaction of the sample under a predetermined
temperature and pressure.
[0002] An apparatus for initiating and/or promoting a chemical and/or physical reaction
on a sample by a microwave is known from
US 9,132,406. The apparatus includes a pressure vessel and the pressure vessel defines a reaction
chamber. A sample is put into the reaction chamber for initiating and/or promoting
chemical and/or physical high-pressure reaction on the sample. Furthermore, the pressure
vessel includes an insulation lining (a so-called liner) which serves as an insulator
of the pressure vessel to improve a thermal resistance of the pressure vessel. The
insulation lining is preferably made of plastic, PTFE, ceramic or tantalum. In addition,
the insulation lining serves for preventing an inner lining of the pressure vessel
from being chemically contaminated and corroded by the reactant and/or product and
protecting the inner lining of the pressure vessel.
[0003] Furthermore, a lid is provided above the pressure vessel and configured to open or
close the pressure vessel. When the lid closes the pressure vessel, an upper portion
of the pressure vessel and the lid are clamped by a clamp, thereby sealing the pressure
vessel. More specifically, when the lid rests on the upper part of the pressure vessel,
both clamp halves which together form the circular metal clamp, can be closed. When
the two steel clamp halves are closed, they can be secured against each other by a
bolt.
[0004] A thread of the bolt engages in an opposite thread formed in one of the two clamp
halves so that the latter can be pulled against each other. A part of the thread of
the bolt which projects beyond the opposite thread of one clamp half has a length
such that the bolt is also thereby prevented from being screwed out in a direction
away from the clamp. In this state, the bolt is manually rotated for locking the two
clamp halves so that the lid and the pressure vessel are air-tightly fixed.
[0005] In the air-tightly fixed state, a gas is supplied into the reaction chamber to increase
an internal pressure of the pressure vessel. In this time, a microwave is generated
to heat the sample, thereby performing a reaction of the sample. After the reaction
is terminated, the clamp is loosened by manually untightening the bolt and the sample
is removed from the pressure vessel.
[0006] In such a conventional experiment apparatus, as explained above, after the sample
is put into the pressure vessel the clamp should be air-tightly fixed by manually
tightening the bolt and after the reaction is completed, the clamp should be loosened
by manually untightening the bolt. Depending on a type of the sample, a gas harmful
to a human body may be generated as a reaction product. As a result, this poses a
problem in that an user may inhale the harmful gas when personally fixing and releasing
the clamp.
[0007] Since the clamp is manually fixed, the applied force for tightening the bolt can
vary each time. If the bolt is weakly tightened, the sealing of the pressure vessel
may not be properly achieved. In the case where a reaction occurs in such a state
that the pressure vessel is not properly sealed, the reaction may not be performed
in the correct way and a gas may be leaked from the pressure vessel. This circumstance
may lead to disaster.
[0008] Further, during the reaction, depending on the type of materials used as a reactant,
an acid material may be produced as a product. The produced acid material cause corrosion
of parts and pipes for transporting gas provided inside the experiment apparatus.
If such parts and pipes undergo corrosion, then the affected parts and pipes need
to be replaced. However, since each parts and pipes are independently arranged inside
the experiment apparatus, it would be difficult for an ordinary user to replace the
parts and pipes which should be delicately dealt with.
[0009] US 6,097,015A reveals a system for microwave sterilization which produces and transmits microwaves
from both ends of a pressure vessel for sterilizing medical waste contained within
a treatment chamber formed by two mutually coupled pressure hulls. The medical waste
is placed inside the chamber. Microwaves generated by generator are reflected by reflector
into chamber along linear guides to generate steam and pressure for carrying out the
sterilization. A liner along sides of pressure hulls is provided to focus microwave
towards the medical waste container.
[0010] It is thus an objective of the invention to provide an automated experiment apparatus
and an automated experiment method which are capable of automatically performing an
experiment from beginning to end without a manual operation. As a result, according
to at least preferred embodiments, a risk of gas leakage and human exposure to a harmful
gas can be reduced. Furthermore, according to at least preferred embodiments, the
parts and pipes for transporting gas can be easily replaced.
[0011] Viewed from one aspect the present invention provides an automated experiment apparatus,
comprising: a pressure vessel having an opening to define a sample receiving chamber
therein, the pressure vessel including a vessel flange having a circular outer shape
with a radius about a central axis of the pressure vessel; a sample holding member
configured to hold a sample to be accommodated in the sample receiving chamber, the
sample holding member including a holder flange having an outer circular shape of
the same radius as the vessel flange and configured to make contact with the vessel
flange to close the opening; a sensing unit configured to sense at least one of an
upper position and a lower position of the sample holding member; a plurality of clamps
configured to air-tightly engage the holder flange of the sample holding member and
the vessel flange of the pressure vessel wherein each of the plurality of clamps includes
a clamp head having a groove configured to engage with the holder flange and the vessel
flange, and an actuator connected to the clamp head; a clamping sensor configured
to sense a top dead point of the clamp head at which the clamp head is fully pushed
out by the actuator to air-tightly engage the holder flange; a gas transfer unit having
a gas supplier and a gas discharger connected to the sample holding member and configured
to supply or discharge a gas into or from the pressure vessel; a heating unit configured
to heat the sample receiving chamber; a pressure sensor configured to measure an internal
pressure of the pressure vessel; a user interface configured to receive an input from
an user; and a controller configured to receive the input signal from the user interface
and the sensing signal from a sensing unit to control in response to the input signal
and the sensing signal the actuator of each of the clamps to cause the clamp head
to make a transverse movement in a radial direction of the vessel flange to engage
the holder flange and the vessel flange, to control in response to a clamping sensor
signal received from the clamping sensor the gas transfer unit to supply the gas to
the pressure vessel until the internal pressure of the pressure vessel reaches a predetermined
reaction pressure as indicated by a pressure sensor signal from the pressure sensor,
to control in response to the pressure sensor signal from the pressure sensor the
heating unit to heat the sample receiving chamber, and to control the gas transfer
unit to discharge the gas from the sample receiving chamber.
[0012] Viewed from another aspect the present invention provides an automated experiment
method using an automated experiment apparatus, comprising moving a sample holding
member of the automated experiment apparatus down to make a holder flange of the automated
experiment apparatus contact with a vessel flange of the automated experiment apparatus
by driving a lifter in response to a control signal sent by a controller of the automated
experiment apparatus, wherein the sample holding member is configured to hold a sample
to be accommodated in a sample receiving chamber of the automated experiment apparatus;
engaging the holder flange and the vessel flange to air-tightly fix a sample holding
member and a pressure vessel of the automated experiment apparatus by the controller
sending control signals to actuators of the automated experiment apparatus to move
clamp heads of clamps included in the automated experiment apparatus transversely
toward the holder flange and the vessel flange; supplying a gas to a sample receiving
chamber of the automated experiment apparatus until the internal pressure of the pressure
vessel reaches a predetermined reaction pressure as indicated by a pressure sensor
signal from a pressure sensor; heating the sample receiving chamber after the supplying;
discharging the gas from the sample receiving chamber; disengaging the holder flange
and the vessel flange by the controller sending control signals to the actuators to
move the clamp heads transversely away from the holder flange and the vessel flange;
and moving the sample holding member up by driving the lifter in response to the control
signal sent by the controller.
[0013] Embodiments of the invention will now be described, by way of example only, with
reference to the accompanying drawings, wherein:
Fig. 1 is a perspective view of an automated experiment apparatus according to one
embodiment of the present disclosure.
Fig. 2 is a schematic sectional view of the structure of a pressure vessel shown in
Fig. 1.
Fig. 3 is a partial side view of the automated experiment apparatus of Fig. 1.
Fig. 4 is a perspective view of the clamp shown in Fig. 1.
Fig. 5 is a plan view showing a state in which a cover and the pressure vessel are
not clamped by the clamp shown in Fig. 1.
Fig. 6 is a plan view showing a state in which the cover and the pressure vessel are
clamped by the clamp shown in Fig. 1.
Fig. 7 is a control block diagram for explaining the control operation of the respective
units of the automated experiment apparatus of Fig. 1.
Figs. 8A to 8H show each of the steps of an automated experiment method by using the
automated experiment apparatus of Fig. 1.
Figs. 9A to 9C show flowcharts for explaining the automated experiment method using
the automated experiment apparatus of Fig. 1.
Fig. 10 is a gas control module of the automated experiment apparatus of Fig. 1.
Fig. 11 is a circuit diagram of the gas control module of Fig. 10.
Fig. 12 is an exploded perspective view of the automated experiment apparatus of Fig.
1.
Fig. 13 shows steps for inserting a connecting block of the gas control module to
a connecting groove of the housing of the automated experiment apparatus of Fig. 1.
[0014] Specific embodiments for realizing an idea of the present disclosure will now be
described in detail with reference to the accompanying drawings.
[0015] In describing the present disclosure, if it is determined that the specific descriptions
of configurations or functions of the related art may make obscure the spirit of the
present disclosure, the detailed descriptions thereof will be omitted.
[0016] When there is a description that one component is "connected", "coupled", "supplied",
"transferred" or "brought into contact" to or with another component, it is to be
understood that one component may be connected, coupled, supplied, transferred or
brought into contact to or with another component either directly or through the intervention
of a third component.
[0017] The terms used herein are used merely for the purpose of describing specific embodiments
and are not intended to limit the present disclosure. A singular expression includes
a plural expression unless explicitly mentioned otherwise.
[0018] In the subject specification, expressions such as "upper", "lower", "side" and the
like are based on the drawings. If the orientation of a subject matter is changed,
the expressions may also be changed accordingly.
[0019] Hereinafter, specific configurations of an automated experiment apparatus according
to one embodiment of the present disclosure will be described in detail with reference
to Figs. 1 to 7.
[0020] Referring to Figs. 1 to 3, the automated experiment apparatus 10 according to one
embodiment of the present disclosure may include a housing 100, a pressure vessel
200 provided inside the housing 100 and including a sample receiving chamber 220 (see
Fig. 2), and a clamp 300 configured to selectively air-tightly fix a sample holding
member 120 and the pressure vessel 200.
[0021] The housing 100 provides an outer shell of the automated experiment apparatus 10.
The pressure vessel 200 is installed inside the housing 100. The automated experiment
apparatus 10 may further include a display 104 disposed on the housing 100 and configured
to display the current state of the apparatus 10 or other information to an user,
and a user interface 106 disposed on the housing 100 and configured to receive an
input from the user, generate an input signal and send it to a controller 400 shown
in Fig. 7. A transparent window 108 is configured to cover an upper portion of the
housing 100. The window 108 functions as a safety shield curtain capable of preventing
leakage of a gas to the outside. The user interface 106 is positioned outside of the
transparent window 108. While not shown in the drawings, a fan for discharging a gas
may be installed inside the housing 100.
[0022] In the housing 100, there is provided the sample holding member 120 configured to
hold a sample P to be accommodated within the sample receiving chamber 220 and selectively
cover an upper end opening 202 of the pressure vessel 200. Further, in the housing,
there are provided a moving unit 110 configured to vertically move the sample holding
member 120, a gas transfer unit 130 connected to the sample holding member 120 and
configured to transfer a gas into the pressure vessel 200 and a sensing unit 140.
[0023] The moving unit 110 is configured to vertically move the sample holding member 120
and provided on the front side of the housing 100. The moving unit 110 includes a
lifter 112 configured to provide a driving force to move the sample holding member
120 vertically, a guide 114 configured to guide the vertical movement of the sample
holding member 120, and a moving frame 116 connected to the sample holding member
120 and the lifter 112 and configured to be moved vertically by the lifter 112. The
guide 114 is attached on the front side surface of the housing and extends vertically.
The moving frame 116 is engaged with the guide 114. The vertical movement of the moving
frame 116 is guided by the guide 114.
[0024] The lifter 112 is, for example, a hydraulic cylinder or a screw jack. In addition,
any suitable member which can provide a driving force for vertically moving the sample
holding member 120 may be used as the lifter 112. The guide 114 may be one or more
bars installed on a wall surface of the housing 100 and formed to extend in a vertical
direction. The moving frame 116 may have a bar shape and extend horizontally. The
moving frame 116 is guided by the guide 114 when the lifter 112 is driven.
[0025] The sample holding member 120 may be vertically moved between an upper position and
a lower position by the moving unit 110, as shown in Fig. 3. The term "upper position"
used herein refers to the uppermost position to which the sample holding member 120
can be moved up with respect to the housing 100. The term "lower position" used herein
refers to the lowermost position to which the sample holding member 120 can be moved
down with respect to the housing 100.
[0026] The sample holding member 120 may include a holder flange 122 configured to make
contact with the pressure vessel 200 at the lower position, a connection frame 124
configured to interconnect the moving frame 116 and the holder flange 122, and a sample
holder 126 connected to the holder flange 122 and configured to hold the sample P.
[0027] The holder flange 122 is formed in a lower portion of the sample holding member 120.
The holder flange 122 has a circular outer shape of the same radius as a vessel flange
210 of the pressure vessel 200. The connection frame 124 may extend from the upper
surface of the sample holding member 120 and be connected to the center of the moving
frame 116. The sample holder 126 is configured to hold the sample P provided as test
tubes for accommodating a reactant therein. The sample holder 126 may include an upper
disc having a plurality of holes into which the test tubes can be inserted, a lower
disc having a plurality of recesses formed on an upper surface thereof and configured
to accommodate the lower portions of the test tubes, and a central beam configured
to interconnect the upper disc and the lower disc. Thus, the sample P may be held
in the sample holder 126 as the test tubes are inserted into the holes of the upper
disc and the lower portions of the test tubes are accommodated in the recesses of
the lower disc.
[0028] In Figs. 1 and 7, the gas transfer unit 130 is configured to supply the gas, for
example, a N
2 gas, into the pressure vessel 200. For this purpose, the gas transfer unit 130 includes
a gas supplier 132 configured to supply the gas into the pressure vessel 200, a gas
discharger 136 configured to discharge the gas from the pressure vessel 200, a gas
supply line 134 connected at the opposite ends to the sample holding member 120 and
the gas supplier 132, and a gas discharge line 138 connected at the opposite ends
to the sample holding member 120 and the gas discharger 136.
[0029] The gas supplier 132 and the gas discharger 136 may include a gas transfer means,
and the gas transfer means is for example, a blower fan 105 (see Fig. 12) provided
inside the housing 100. The gas supplier 132 may further include a separate storage
container configured to store a specified gas to be supplied. The gas transfer means
may be connected to the storage container so that the gas stored in the storage container
can be supplied into the pressure vessel 200 via the gas supply line 134. The gas
discharger 136 may further include a separate post-treatment means. The gas transfer
means may be connected to the post-treatment means so that the gas existing in the
pressure vessel 200 can be discharged to the post-treatment means via the gas discharge
line 138.
[0030] The gas supplier 132 and the gas discharger 136 may be provided inside the housing
100. However, the present disclosure is not limited thereto. The gas supplier 132
and the gas discharger 136 may be separately provided outside the housing 100 and
may be connected to the gas supply line 134 and the gas discharge line 138.
[0031] The gas supply line 134 and the gas discharge line 138 are connected at one end to
the sample holding member 120 and are formed to extend to the lower surface of the
sample holding member 120 through the sample holding member 120. Thus, the gas supply
line 134 and the gas discharge line 138 communicate with the sample receiving chamber
220 inside the pressure vessel 200 when the sample holding member 120 is fastened
to the pressure vessel 200 in an air-tight manner.
[0032] The sensing unit 140 includes an upper position sensor 142 configured to sense whether
the sample holding member 120 is located at the upper position, a lower position sensor
144 configured to sense whether the sample holding member 120 is located at the lower
position, a pressure sensor 146 configured to measure an internal pressure of the
pressure vessel 200, and a temperature sensor 148 configured to measure an internal
temperature of the pressure vessel 200.
[0033] The upper position sensor 142 and the lower position sensor 144 are respectively
installed in a position corresponding to the upper position of the moving frame 116
and a position corresponding to the lower position of the moving frame 116. The upper
position sensor 142 and the lower position sensor 144 may be, for example, a magnetic
sensor. When the moving frame 116 is located in a predetermined upper position or
lower position, a contact point provided in the moving frame 116 makes contact with
a magnet disposed at the upper position or the lower position, whereby an electric
current flows through the contact point. An electrical signal thus generated is transmitted
to a controller 400 (see Fig. 7) so that the position of the moving frame 116 can
be detected.
[0034] The pressure vessel 200, which is a cylindrical container, may be made of a material
capable of resisting a high temperature and a high pressure. The pressure vessel 200
has an opening 202 formed in the upper surface thereof. An inner lining 204 of the
pressure vessel 200 is made of a rigid material having a superior heat resistance
such as Teflon which has superior heat and acid resistance.
[0035] The pressure vessel 200 further includes the vessel flange 210 provided as the upper
end portion of the pressure vessel 200 so as to surround the opening 202. The vessel
flange 210 has a circular outer shape with a radius about a central axis 201 of the
pressure vessel 200.
[0036] The pressure vessel 200 further includes a heating unit 230 configured to heat the
sample receiving chamber 220, and a cooling unit 240 configured to cool the sample
receiving chamber 220 by circulating a coolant along the periphery of the sample receiving
chamber 220.
[0037] As shown in Fig. 2, the heating unit 230 may include a microwave generator 232 configured
to generate a microwave, a magnetron 234 configured to transfer the microwave generated
in the microwave generator 232 to the sample receiving chamber 220, and an antenna
236 connected to the sample receiving chamber 220 and configured to transmit the microwave
guided by the magnetron 234 to the sample receiving chamber 220.
[0038] The cooling unit 240 may include a coolant supplier 242 configured to store and supply
a coolant. In the pressure vessel 200, there may be formed a coolant inlet 244 for
supplying the coolant to a coolant circulation line connected to the coolant supplier
242 and provided to surround the outer surface of the pressure vessel 200 and a coolant
outlet 246 for recovering the coolant discharged from the coolant circulation line.
[0039] Referring to Figs. 4 to 6, the clamp 300 is provided to selectively air-tightly engage
the holder flange 122 of the sample holding member 120 and the vessel flange 210 of
the pressure vessel 200. The clamp 300 may include a clamp body 320, a clamp head
310 and an actuator 330 connected to the clamp head 310. The clamp head 310 includes
a groove 312 configured to engage with the holder flange 122 and the vessel flange
210. The actuator 330 actuates the clamp head 310 to make the clamp head move in a
radial direction of the vessel flange 210. When the clamp head 310 moves toward the
vessel flange 210 and the holder flange 122, the groove 312 is engaged with the holder
flange 122 and the vessel flange 210 together so that the holder flange 122 and the
vessel flange 210 are air-tightly fixed to each other. When the clamp head 310 moves
back from the vessel flange 210 and the holder flange 122, the groove 312 is disengaged
from the holder flange 122 and the vessel flange 210 so that the holder flange 122
and the vessel flange 210 are not fixed to each other. For example, the actuator 330
may be one of a hydraulic cylinder, a screw jack or the like.
[0040] In this embodiment, the holder flange 122 and the vessel flange 210 may have a ring
shape and the clamp head 310 may have an arc shape. The clamp 300 may be a C-type
clamp as the groove 312 has a C-like vertical cross section. Specifically, the vertical
cross section of the groove 312 may be defined by a vertical surface 312b and two
slant surfaces 312a formed to obliquely extend from the upper and lower ends of the
vertical surface 312b.
[0041] Slant surfaces are also formed in the edge portions of the holder flange 122 and
the vessel flange 210 that correspond to the slant surfaces 312a of the clamp 300.
In a state in which the slant surfaces of the holder flange 122 and the vessel flange
210 and the slant surfaces 312a of the clamp 300 are brought into contact with each
other, the clamp head 310 further moves toward the holder flange 122 and the vessel
flange 210, thereby compressing the holder flange 122 and the vessel flange 210 against
each other. In this manner, the holder flange 122 and the vessel flange 210 can be
air-tightly sealed.
[0042] Furthermore, a clamping sensor 322 configured to sense the position of the clamp
head 310 may be provided to the clamp body 320. For example, the clamping sensor 322
is capable of accurately sensing a top dead point of the clamp head 310, at which
the clamp head 310 is fully pushed out from the clamp body 320 by the actuator 330,
as shown in Fig. 6, and a bottom dead point of the clamp head 310, at which the clamp
head 310 is fully pulled into the clamp body 320 by the actuator 330, as shown in
Fig. 5. For example, the clamping sensor 322 may be a magnetic sensor. When the clamp
head 310 is located at the top dead point or the bottom dead point, a contact point
provided in the end portion of a piston rod connected to the clamp head 310 is brought
into contact with a magnet disposed in a relevant position inside the clamp body 320,
whereby an electric current flows through the contact point. An electrical signal
thus generated is transmitted to the sensor signal receiving unit 414 (see Fig. 7)
so that the position of the moving frame 116 can be detected.
[0043] In the meantime, one or more clamps 300 are disposed around the opening 202 of the
pressure vessel 200 and the clamp heads 310 thereof are configured to move toward
or away from the pressure vessel 200. If a plurality of clamps 300 are provided, the
clamps 300 are disposed around the pressure vessel 200 at predetermined intervals
so that a plurality of the clamp heads 310 can make contact with the holder flange
122 and the vessel flange 210 at multiple points. The clamp heads 310 are configured
to move toward or back from the holder flange 122 and the vessel flange 210, thereby
air-tightly fixing or unfixing the sample holding member 120 and the pressure vessel
200. In order to enhance the air-tightness of the sample holding member 120 and the
pressure vessel 200, an elastic O-ring may be provided on the mutually-facing surface
of the holder flange 122 and/or the vessel flange 210.
[0044] Referring to Fig. 7, the controller 400 is configured to automatically perform a
reaction process under a predetermined temperature and pressure in a state in which
the sample holding member 120 is air-tightly fixed to the pressure vessel 200 and
a sample P is accommodated within the sample receiving chamber 220. The controller
400 comprises an interfacing circuit 410, a memory 420 and a processor 430. The interfacing
circuit 410 is coupled to the processor 430, and the memory 420 is coupled to the
processor 430.
[0045] The interfacing circuit 410 comprises an input receiving unit 412 configured to receive
an input through the user interface 106, a sensor signal receiving unit 414 configured
to receive sensor signals from various sensors including the upper position sensor
142, the lower position sensor 144, the pressure sensor 146, the temperature sensor
148 and the clamping sensor 322, and an operation control unit 416 coupled to the
lifter 112 of the moving unit 110, the gas supplier 132 and the gas discharger 136
of the gas transfer unit 130, the microwave generator 232 of the heating unit 230,
the coolant supplier 242 of the cooling unit 240 and the actuator 330 of the clamp
300.
[0046] The upper position sensor 142 is coupled to the sensor signal receiving unit 414
and configured to send a sensing signal of whether the sample holding member 120 is
located at the upper position to the sensor signal receiving unit 414. The lower position
sensor 144 is coupled to the sensor signal receiving unit 414 and configured to send
a sensing signal of whether the sample holding member 120 is located at the lower
position to the sensor signal receiving unit 414. The pressure sensor 146 is coupled
to the sensor signal receiving unit 414 and configured to send a sensing signal of
the internal pressure of the pressure vessel 200 to the sensor signal receiving unit
414. The temperature sensor 148 is coupled to the sensor signal receiving unit 414
and configured to send a sensing signal of the internal temperature of the pressure
vessel 200 to the sensor signal receiving unit 414.
[0047] The operation control unit 416 is configured to send a control signal to the lifter
112 to move the moving frame vertically. The operation control unit 416 is further
configured to send a control signal to the gas supplier 132 and the gas discharger
136 for supplying/discharging the gas into/from the pressure vessel 200. The operation
control unit 416 is further configured to send a control signal to the microwave generator
232 for heating the pressure vessel 200. The operation control unit 416 is further
configured to send a control signal to the coolant supplier 242 for cooling the pressure
vessel 200. Moreover, the operation control unit 416 is further configured to send
a control signal to the actuator 330 to move the moving frame 116 vertically.
[0048] Hereinafter, an automated experiment method for automatically performing an experiment
using the automated experiment apparatus 10 configured as mentioned above will be
described with reference to Figs. 8A to 8H, 9A to 9C and 10.
[0049] As shown in Fig. 9A, the automated experiment method according to one embodiment
of the present disclosure is started by a start signal input from an user through
the user interface 106. Along with the input of the start signal, the user may input
specific reaction conditions such as a reaction temperature, a reaction pressure and
a reaction time. These reaction conditions may be pre-stored in the memory 420.
[0050] If the start signal is inputted through the user interface 106, the input receiving
unit 412 of the controller 400 receives the start signal (S11). As the input receiving
unit 412 receives the start signal, the controller 400 sends a control signal to the
lifter 112 to move the sample holding member 120 down to the lower position.
[0051] Specifically, if the start signal is received by the input receiving unit 412 (S11),
the controller 400 may determine whether the sample holding member 120 is sensed by
the upper position sensor 142 (S12). If the upper position sensor 142 senses the sample
holding member 120 being properly located at the upper position, the controller 400
sends a control signal to the lifter 112 and the lifter 112 is driven to move the
sample holding member 120 downward (S14).
[0052] If the upper position sensor 142 fails to sense the sample holding member 120 being
properly located at the upper position, the controller 400 stops all operations of
the automated experiment apparatus 10 and generates alarm code 1 (S122). As a result,
prior to starting the downward movement of the sample holding member 120, it become
possible to determine whether the sample holding member 120 is located in the correct
position before the downward movement is started. This makes it possible to prevent
damage or erroneous operation of the apparatus which may occur when the downward movement
of the sample holding member 120 is started from the wrong position due to an unexpected
error.
[0053] The lifter 112 is controlled by the controller 400 to accurately generate a driving
force at a predetermined magnitude and move the sample holding member 120 down to
the lower position. The controller 400 verifies whether the sample holding member
120 is sensed by the lower position sensor 144 during a first preset time after the
controller 400 sends a control signal to the lifter 112 to move down the sample holding
member 120 (S16). If the lower position sensor 144 senses the sample holding member
120 being properly located at the lower position, the controller 400 sends control
signals to the plurality of actuators 330.
[0054] If the lower position sensor 144 fails to sense the sample holding member 120 during
the first preset time, the controller 400 stops all operations of the automated experiment
apparatus 10 and generates alarm code 2 (S162). This makes it possible to prevent
damage or erroneous operation of the apparatus which may occur when the holder flange
122 and the vessel flange 210 are clamped in a state in which the sample holding member
120 is not properly positioned at the lower position due to an unexpected error despite
the provision of the predetermined driving force.
[0055] After the downward movement step (S1) is completed, the controller 400 sends control
signals to the plurality of actuators 330, and the clamp heads 310 move transversely
toward the holder flange 122 and the vessel flange 210 to engage the holder flange
122 and the vessel flange 210 (S2). As a result, the sample holding member 120 and
the pressure vessel 200 are air-tightly fixed to each other.
[0056] Specifically, each of the clamp heads 310 of the clamps 300 begins to be pushed out
from the corresponding clamp bodies 320 (S22). At this step, the clamps 300 are controlled
to be operated synchronously. Further, in order to give a constant clamping force
to the holder flange 122 and the vessel flange 210 every time the experiment is performed,
the actuators 330 can be controlled to be stretched to a predetermined length.
[0057] The controller 400 verifies whether the clamp head 310 is sensed to be located at
the top dead point by the clamping sensors 322 during a second preset time after the
controller 400 sends control signals to the actuators 330 for stretching thereof (S24).
If the clamping sensors 322 senses the clamp heads 310 at the top dead point, it is
considered that the sample holding member 120 and the pressure vessel 200 have been
air-tightly fixed completely.
[0058] If at least one of the clamping sensors 322 fails to sense the corresponding clamp
head 310 at the top dead point during the second preset time, the controller 400 stops
all operations of the automated experiment apparatus 10 and generates alarm code 3
(S242). This makes it possible to prevent damage of the apparatus or leakage of a
harmful gas, which may occur when the clamp heads 310 are not located at the predetermined
top dead point due to an unexpected error and when a reaction is started in a state
in which the air-tight fixing of the holder flange 122 and the vessel flange 210 by
clamping is not fully achieved.
[0059] As shown in Fig. 9B, the gas supplier 132 is operated to supply a specified gas to
the sample receiving chamber 220 (S3) after the clamping step (S2) is completed.
[0060] Specifically, the operation of the gas supplier 132 may be started to supply a specified
gas into the pressure vessel 200 for a predetermined period of time (S32). The gas
may be, for example, an N
2 gas.
[0061] The supply of the gas using the gas supplier 132 may be performed until the internal
pressure of the pressure vessel 200 reaches a predetermined reaction pressure. For
this purpose, the amount of the supply gas required for creating the predetermined
reaction pressure may be automatically calculated according to an algorithm stored
in the controller 400. The amount of the gas thus calculated may be supplied into
the pressure vessel 200 via the gas supply line 134.
[0062] During supplying of the gas, the controller 400 determines whether the internal pressure
of the pressure vessel 200 measured by the pressure sensor 146 is higher than a pressure
limit (S34).
[0063] If the internal pressure of the pressure vessel 200 measured by the pressure sensor
146 exceeds the pressure limit, the controller 400 may stop all operations of the
automated experiment apparatus 10 and may generate alarm code 4 (S342). This makes
it possible to prevent breakage of the pressure vessel 200 which may occur when the
internal pressure exceeds the pressure limit due to an unexpected error.
[0064] After the gas supply step (S3) is completed , a heating step (S4) for heating the
sample receiving chamber 220 is started.
[0065] Specifically, after the supply of the gas is completed, the operation of the microwave
generator 232 is started to transfer a microwave to the pressure vessel 200 via the
antenna 236 for a predetermined period of time (S42). As a result, the internal temperature
of the pressure vessel 200 gets higher. The interior of the pressure vessel 200 may
be heated so that the internal temperature of the pressure vessel 200 reaches a predetermined
reaction temperature. To that end, the amount of the microwave required for achieving
the predetermined reaction temperature may be automatically calculated according to
a specified algorithm stored in the controller 400.
[0066] When the pressure vessel 200 is heated by the microwave, the controller 400 may determine
whether the internal temperature of the pressure vessel 200 measured by the temperature
sensor 148 reaches a predetermined temperature limit(S44). In this regard, the temperature
limit may be set at a temperature above which explosion may occur inside the pressure
vessel 200 by the sample P or a temperature above which other components inside the
pressure vessel 200 may be damaged.
[0067] If the internal temperature of the pressure vessel 200 measured by the temperature
sensor 148 reaches or exceeds the temperature limit, the controller 400 may stop all
operations of the automated experiment apparatus 10 and may generate alarm code 5
(S442).After the heating step (S4) is completed and the reaction is terminated, the
sample receiving chamber 220 is cooled by circulating a coolant through a circumference
of the pressure vessel 200, and the gas is discharged from the sample receiving chamber
220 (S5).
[0068] Specifically, the reaction is terminated as the operation of the microwave generator
232 is stopped (S52). As the reaction is terminated, the coolant supplier 242 starts
to operate and the coolant is supplied to and circulated along the periphery of the
pressure vessel 200 for a predetermined period of time (S54). As the cooling is performed,
the operation of the gas discharger 136 is started and the gas is discharged from
the pressure vessel 200 via the gas discharge line 138 for a predetermined period
of time (S56). At this time, the gas may be discharged until the internal pressure
of the pressure vessel 200 reaches the atmospheric pressure (1 atm). This makes it
possible to prevent the occurrence of unnecessary explosions when the pressure vessel
200 is opened (S58).
[0069] As shown in Fig 9C, the holder flange 122 and the vessel flange 210 are unclamped
(S6) after the cooling and gas discharging step (S5) is completed.
[0070] Specifically, each of the clamp heads 310 of the clamps 300 begin to be pulled into
the corresponding clamp bodies 320 (S62). At this step, the clamps 300 are controlled
to be operated synchronously. The actuators 330 can be controlled to be shrunk to
a predetermined length.
[0071] The controller 400 verifies whether the clamp head 310 is sensed to be located at
the bottom dead point by the clamping sensors 322 during a third preset time after
the controller 400 sends control signals to the actuators 330 for shrinking thereof
(S64). If the clamping sensors 322 senses the clamp heads 310 at the bottom dead point,
it is considered that the sample holding member 120 and the pressure vessel 200 have
been unfixed completely.
[0072] If at least one of the clamping sensors 322 fails to sense the corresponding clamp
head 310 at the bottom dead point during the third preset time, the controller 400
stops all operations of the automated experiment apparatus 10 and generates alarm
code 6 (S642). This makes it possible to prevent damage or erroneous operation of
the apparatus which may occur when the clamp head 310 is not located at the predetermined
bottom dead point due to an unexpected error and when the upward movement of the sample
holding member 120 is started in a state in which the unclamping of the holder flange
122 and the vessel flange 210 is not fully achieved.
[0073] After the unclamping step (S6) is completed, the sample holding member 120 is moved
up to the upper position by the lifter 112 (S7).
[0074] Specifically, the controller 400 controls the lifter 112 to move the sample holding
member 120 upward (S72). In this way, the lifter 112 is controlled by the controller
400 to accurately generate a driving force at a predetermined magnitude and move the
sample holding member 120 up to the upper position. The controller 400 verifies whether
the sample holding member 120 is sensed by the upper position sensor 142 during a
fourth preset time after the controller 400 sends a control signal to the lifter 112
to move up the sample holding member 120 (S74). If the upper position sensor 142 senses
the sample holding member 120 being properly located at the upper position, the automated
experiment process is completed.
[0075] If the upper position sensor 142 fails to sense the sample holding member 120 during
the fourth preset time, the controller 400 stops all of the operations of the automated
experiment apparatus 10 and generates alarm code 7 (S742). This makes it possible
to prevent the erroneous operation of the apparatus which may occur when the next
experiment is initiated in a state in which the sample holding member 120 is not properly
positioned at the upper position due to an unexpected error despite the provision
of the predetermined driving force.
[0076] Turning now to Figs. 1 and 7, these figures show the gas transfer unit 130 connected
to the sample holding member 120. Specifically, the gas supplier 132 and the gas discharger
136 of the gas transfer unit 130 are connected to the sample holding member 120 via
the gas supply line 134 and the gas discharge line 138, respectively, and the gas
supply line 134 and the gas discharge line 138 are arranged to go inside the housing
100. However, if such gas lines disposed in the housing 100 are corroded, it would
be difficult for an ordinary user to fix the same.
[0077] To solve this problem, the automated experiment apparatus 10 according to one embodiment
of the present disclosure may employ a gas control module 500 detachably accommodated
in the housing 100, making it easy for an unskilled person to replace gas pipes constituting
a part of the gas supply line 134 and the gas discharge line 138. Hereinafter, specific
configurations of the gas control module 500 will be described in detail with reference
to Figs. 10 to 13.
[0078] Referring to Figs. 10 to 13, the gas control module 500 is detachably accommodated
in the housing 100 and includes gas pipes constituting a part of the gas supply line
134 and the gas discharge line 138 which provide flow paths for the gas supplied to
or discharged from the pressure vessel 200. Further, the gas control module 500 also
includes various valve devices for controlling a supply path or a discharge path of
the gas.
[0079] The gas control module 500 includes a base panel 502, a connecting block 510 connected
at one side of the base panel 502, a gas input valve 520 configured to open or close
the gas supply line 134, a gas output valve 530 configured to open or close the gas
discharge line 138 and a relief valve 540 configured to open a bypass line for a rapid
discharging of the gas when the pressure inside the pressure vessel 200 reaches or
exceeds the pressure limit.
[0080] Moreover, a space for accommodating the gas control module 500 is formed inside the
housing 100 and an inner hole 101 (see, Fig. 12) communicating with a lower portion
of the housing 100 is formed at the bottom surface of said space.
[0081] Further, various lines and connectors extended from the gas control module 500 pass
through this inner hole 101, such as an input connector 522 and an output connector
524 respectively extended from the gas supply line 134 and the gas discharge line
138. The input connector 522 and the output connector 524 are connected to connection
ports (not shown) of the pressure vessel 200 within the housing 100.
[0082] Moreover, the space in the housing 100 where the gas control module 500 is received
may be covered by a back cover 103. The back cover 103 is configured to open said
space of the housing 100 when the gas control module 500 is being installed in or
detached from the housing 100.
[0083] The base panel 502 is provided to support pipes for supplying or discharging the
gas and may be fixed to the housing 100 by bolts and nuts. Alternatively, the base
panel 502 may be detachably attached to the housing 100 and the detaching or attaching
of the base panel 502 is guided by the connecting block 510 attached at one side of
the base panel 502.
[0084] When the base panel 502 is attached to the housing 100, the connecting block 510
is inserted to a connecting groove 102 concavely formed from an edge of a wall of
the housing 100 and determines an installing position of the base panel 502. Accordingly,
it is easy even for an unskilled person to open the back cover 103 and attach or detach
the base panel 502 to or from the housing 100.
[0085] Meanwhile, a manual valve 512, an emergency valve 514 and a gas input port 516 are
provided to the connecting block 510.
[0086] The manual valve 512 may be provided for adjusting a pressure of the gas supplied
from the gas supplier 132 such as a gas bombe in a laboratory when the automated experiment
apparatus 10 is initially set up in the laboratory. To this end, an initial pressure
gauge 504 may be provided to the base panel 502, and the initial pressure gauge 504
is connected to the manual valve 512 so that an installer can check the pressure of
the gas when adjusting the initial pressure of the gas. After the initial adjustment
of the pressure of the gas is finished, the manual valve 512 may not be touched during
the normal operation.
[0087] The emergency valve 514 may be used to manually discharge the gas from the pressure
vessel 200 when an alarm is generated by the controller 400 during the experiment.
For this, the emergency valve 514 is configured to manually open or close a bypass
line bypassing the gas output valve 530.
[0088] The gas input port 516 is configured to be engaged with the gas supply line 134 extended
from the gas supplier 132. Further, a line is extended from the gas input port 516
to the pressure vessel 200.
[0089] The gas input valve 520 is installed to the base panel 520 and configured to be provided
on the gas supply line 134 when the gas control module 500 is installed in the housing
100. The gas input valve 520 is provided on the line extended from the gas input port
516 so as to open or close the gas supply line 134 and configured to be controlled
by the controller 400. For example, the gas input valve 520 may be a solenoid valve
that is electrically connected to the controller 400.
[0090] Further, the input connector 522 is provided at an end of the line on which the gas
input valve 520 is provided. The input connector 522 is connected to an input line
extended from the sample holding member 120. The check valve 526 is provided between
the gas input valve 520 and the input connector 522, to prevent a gas reflux toward
the gas input valve 520.
[0091] The gas output valve 530 may be attached to the base panel 502 and located in the
middle of the gas discharge line 138 when the gas control module 500 is installed
in the housing 100. The gas output valve 530 is provided on the gas discharge line
138 which is extended from the sample holding member 120 and connected to the blower
fan 105. The gas output valve 530 is configured to open or close the gas discharge
line 138 and the controller 400 is configured to control the gas output valve 530.
For example, the gas discharge valve 530 may be a solenoid valve that is electrically
connected to the controller 400.
[0092] The relief valve 540 may be attached to the base panel 502 and located in the middle
of the bypass line bypassing the gas output valve 530 when the gas control module
500 is installed in the housing 100. Further, the relief valve 540 is configured to
open the bypass line only at a pressure exceeding a preset pressure limit such as
200 bars. As a result, if the pressure of the gas inside the pressure vessel 200 or
the gas discharge line 138 exceeds the pressure limit, the relief valve 540 is configured
to be automatically opened and the gas is discharged therefrom through the relief
valve 540. Consequently, an accident can be prevented by opening of the relief valve
540 even when the user failed to open the emergency valve 514. The relief valve 540
can be preset to be opened under a pressure higher than the pressure limit at which
the alarm will be also generated by the controller 400.
[0093] Meanwhile, the gas discharge line 138 extended from the sample holding member 120
and connected to the blower fan 105 includes at least three junctions 532, 534, 536
so that the gas discharge line 138 is separated into at least three branches inside
the housing 100. Among those flow lines, a first junction 532 is a junction from which
a line with the emergency valve 514 provided thereon is branched off and a second
junction 534 is positioned on a downstream line of the first junction 532. The second
junction 534 is a junction from which a line with the gas output valve 530 provided
thereon and a line with the relief valve 540 provided thereon are branched off. Further,
the third junction 536 is where the three lines with the emergency valve 514, the
gas output valve 530 and the relief valve 540 respectively provided thereon all join
together.
[0094] Further, a line extended from the third junction 536 is connected to the blower fan
105 so that the gas is discharged by the blower fan 105. The blower fan 105 is connected
to a discharge port 107 formed through a wall of the housing 100 to discharge the
gas from the housing 100.
[0095] Meanwhile, a regular pressure gauge 506 may be provided on the base panel 502 for
manually checking the pressure of the gas inside the pressure vessel 200 during the
operation of the automated experiment apparatus 10. The regular pressure gauge 506
is connected to a line branched from the middle of a line connecting the second junction
534 and the relief valve 540 so that the pressure inside the pressure vessel 200 can
be shown by the regular pressure gauge 506.
[0096] According to the gas control module 500 of the present embodiment, during the ordinary
operation, the emergency valve 514 and the relief valve 540 are closed, and discharging
of the gas is controlled by the gas output valve 530. Further, when the pressure inside
the pressure vessel 200 increases over the pressure limit, an alarm is generated,
and the user can manually manipulate the emergency valve 514 to discharge the gas
from the pressure vessel 200 or the relief valve 540 is automatically opened to discharge
the gas.
[0097] Hereinafter, the steps for installing the gas control module 500 having aforementioned
configurations into the housing 100 will be described. When installing the gas control
module 500 into the housing 100, the back cover 103 can be opened. After that, the
connecting block 510 can be simply inserted into the connecting groove 102. Then,
the base panel 502 can be fixed to the housing 100 by bolts. After fixing the base
panel 502 to the housing 100, the input connector 522 and the output connector 524
can be connected to the sample holding member 120 or lines extended from the sample
holding member 120. Finally, the third junction 536 can be connected to the blower
fan 105 via a tube and the back cover 103 can be closed. By those simple steps, pipes
and valves inside the housing can be easily installed by installing the gas control
module 500 to the housing 100.
[0098] According to the automated experiment apparatus and the automated experiment method
described above, it is possible to automatically perform an experiment from the beginning
to the end. As a result, it is possible to reduce a risk of gas leakage and human
exposure to a harmful gas due to a manual operation. Further, it is possible to make
it easier to replace members provided for transferring the gas for maintenance.
[0099] Furthermore, the resultant values detected by various kinds of sensors are utilized
during the course of the automated experiment process. In the case where damage or
erroneous operation of the apparatus is likely to occur, the process is stopped and
different alarm codes are generated depending on the situation. This enables the user
to recognize the situation and to take an appropriate measure. It is therefore possible
to prevent irrecoverable damage or erroneous operation of the apparatus.
[0100] While specific embodiments of the present disclosure have been described above, these
embodiments are just one example, and the present disclosure is not limited thereto.
The present disclosure shall be construed to have the broadest scope possible limited
only by the wording of the appended claims.
1. An automated experiment apparatus, comprising:
a pressure vessel (200) having an opening to define a sample receiving chamber (220)
therein, the pressure vessel including a vessel flange (210) having a circular outer
shape with a radius about a central axis of the pressure vessel;
a sample holding member (120) configured to hold a sample to be accommodated in the
sample receiving chamber (220), the sample holding member including a holder flange
(122) having an outer circular shape of the same radius as the vessel flange (210)
and configured to make contact with the vessel flange to close the opening;
a sensing unit (140) configured to sense at least one of an upper position and a lower
position of the sample holding member (120);
a plurality of clamps (300) configured to air-tightly engage the holder flange (122)
of the sample holding member (120) and the vessel flange (210) of the pressure vessel
(200) wherein each of the plurality of clamps includes a clamp head (310) having a
groove (312) configured to engage with the holder flange and the vessel flange, and
an actuator (330) connected to the clamp head;
a clamping sensor (322) configured to sense a top dead point of the clamp head (310)
at which the clamp head (310) is fully pushed out by the actuator (330) to air-tightly
engage the holder flange (122);
a gas transfer unit (130) having a gas supplier (132) and a gas discharger (136) connected
to the sample holding member (120) and configured to supply or discharge a gas into
or from the pressure vessel (200);
a heating unit (230) configured to heat the sample receiving chamber (220);
a pressure sensor (146) configured to measure an internal pressure of the pressure
vessel (200);
a user interface (106) configured to receive an input from an user; and
a controller (400) configured to receive an input signal from the user interface (106)
and a sensing signal from the sensing unit (140) to control in response to the input
signal and the sensing signal the actuator (330) of each of the clamps (300) to cause
the clamp head (310) to make a transverse movement in a radial direction of the vessel
flange (210) to engage the holder flange (122) and the vessel flange (210), to control
in response to a clamping sensor signal received from the clamping sensor (322) the
gas transfer unit (130) to supply the gas to the pressure vessel (200) until the internal
pressure of the pressure vessel (200) reaches a predetermined reaction pressure as
indicated by a pressure sensor signal from the pressure sensor (146), to control in
response to the pressure sensor signal from the pressure sensor (146) the heating
unit (230) to heat the sample receiving chamber (220), and to control the gas transfer
unit (130) to discharge the gas from the sample receiving chamber (220).
2. The apparatus of claim 1, wherein the controller (400) comprises:
a processor (430),
a memory (420) coupled to the processor, and
an interfacing circuit (410) coupled to the processor, the interfacing circuit further
coupled to the user interface (106) and the sensing unit (140) to receive the input
signal and the sensing signal therefrom, the interfacing circuit also coupled to the
clamping sensor (322) to receive a sensor signal therefrom, and the actuator (330)
of each of the clamps to send control signals to the actuators to control operations
of the actuators.
3. The apparatus of claim 2, further comprising:
a lifter (112);
a moving frame (116) connected to the sample holding member (120) and the lifter (112);
and
a guide (114) configured to guide movement of the moving frame,
wherein the interfacing circuit (410) is configured to send a control signal to the
lifter (112) to move the moving frame (116) vertically.
4. The apparatus of claim 2 or 3,
wherein the interfacing circuit (410) is configured to send a control signal to the
gas supplier to supply the gas to the sample receiving chamber, and
wherein the interfacing circuit (410) is configured to send a control signal to the
gas discharger to discharge the gas from the sample receiving chamber.
5. The apparatus of claim 2, 3 or 4, wherein the sensing unit (140) comprises an upper
position sensor (142) configured to sense whether the sample holding member (120)
is located at the upper position and a lower position sensor (144) configured to sense
whether the sample holding member is located at the lower position,
wherein the upper position sensor (142) is coupled to the sensor signal receiving
unit (414) and configured to send a sensing signal of whether the sample holding member
is located at the upper position to the sensor signal receiving unit, and
wherein the lower position sensor (144) is coupled to the sensor signal receiving
unit (414) and configured to send a sensing signal of whether the sample holding member
is located at the lower position to the sensor signal receiving unit.
6. The apparatus of any of claims 2 to 5, wherein the controller (400) is configured
to automatically perform a reaction process under a predetermined temperature and
a predetermined pressure when the sample holding member (120) is air-tightly fixed
to the pressure vessel (200).
7. The apparatus of any preceding claim, wherein the holder flange (122) and the vessel
flange (210) have a ring shape, and the groove (312) has a C-like vertical cross section.
8. The apparatus of any preceding claim, wherein a vertical cross section of the groove
(312) is defined by a vertical surface (312b) and two slant surfaces (312a) formed
to extend from upper and lower ends, respectively, of the vertical surface (312b).
9. The apparatus of any preceding claim , further comprising:
a housing (100) wherein the pressure vessel (200) is provided; and
a gas control module (500) detachably accommodated in the housing,
wherein the gas control module (500) comprises:
a base panel (502) supporting pipes for supplying the gas to or discharging the gas
from the pressure vessel (200), wherein the base panel (502) is detachably accommodated
to the housing (100);
a connecting block (510) attached at one side of the base panel;
a gas input valve (520) provided on the base panel to open or close a gas supply line
(134) for supplying the gas to the pressure vessel; and
a gas output valve (530) provided on the base panel to open or close a gas discharge
line (138) for discharging the gas from the pressure vessel.
10. The apparatus of claim 9, wherein the connecting block (510) is inserted into a connecting
groove (102) recessed on an edge of a wall of the housing (100),
wherein the connecting block (510) determines a position of the base panel (502) when
the gas control module (500) is accommodated in the housing.
11. The apparatus of claim 9 or 10, wherein the gas control module (500) further comprises
a relief valve (540) provided on the base panel (502) and automatically opened when
a pressure in the pressure vessel (200) is equal to or higher than a predetermined
pressure,
wherein an emergency valve (514) is provided on the connecting block (510), configured
to be manipulated manually, and located on a middle of the gas discharge line (138),
and
wherein the gas discharge line includes at least three branches (532, 534, 536) in
the gas control module, and
wherein the emergency valve (514), the gas output valve (530) and the relief valve
(540) are respectively provided on each of the three branches.
12. An automated experiment method using an automated experiment apparatus, comprising:
moving a sample holding member (120) of the automated experiment apparatus down to
make a holder flange (122) of the automated experiment apparatus contact with a vessel
flange (210) of the automated experiment apparatus by driving a lifter (112) in response
to a control signal sent by a controller (400) of the automated experiment apparatus,
wherein the sample holding member (120) is configured to hold a sample to be accommodated
in a sample receiving chamber (220) of the automated experiment apparatus;
engaging the holder flange (122) and the vessel flange (210) to air-tightly fix a
sample holding member (120) and a pressure vessel (200) of the automated experiment
apparatus by the controller sending control signals to actuators (330) of the automated
experiment apparatus to move clamp heads (310) of clamps (300) included in the automated
experiment apparatus transversely toward the holder flange (122) and the vessel flange
(210);
supplying a gas to a sample receiving chamber (220) of the automated experiment apparatus
until the internal pressure of the pressure vessel (200) reaches a predetermined reaction
pressure as indicated by a pressure sensor signal from a pressure sensor (146);
heating the sample receiving chamber (220) after the supplying;
discharging the gas from the sample receiving chamber (220);
disengaging the holder flange (122) and the vessel flange (210) by the controller
(400) sending control signals to the actuators (330) to move the clamp heads (310)
transversely away from the holder flange and the vessel flange; and
moving the sample holding member (120) up by driving the lifter (112) in response
to the control signal sent by the controller.
13. The method of claim 12, wherein the automated experiment apparatus comprises a sensing
unit (140) including an upper position sensor sensing (142) whether the sample holding
member (120) is located at an upper position and a lower position sensor (144) sensing
whether the sample holding member (120) is located at a lower position,
wherein if the upper position sensor (142) fails to sense the sample holding member
located at the upper position before the sample holding member starts to move down,
the controller stops all operations of the automated experiment apparatus and generates
a first alarm (S122), and
wherein if the lower position sensor (144) fails to sense the sample holding member
(120) located at the lower position during the first preset time after the controller
sent the control signal to the lifter to move down the sample holding member, the
controller stops all operations of the automated experiment apparatus and generates
a second alarm (S162).
14. The method of claim 12 or 13, wherein each of the clamps (300) includes a clamping
sensor (322) sensing a position of the clamp head (310), and
wherein if at least one of the clamping sensors (322) fails to sense the corresponding
clamp head (310) positioned at a top dead point during a second preset time after
the controller sends control signals to the actuators for stretching thereof, the
controller stops all operations of the automated experiment apparatus and generates
a third alarm (S242).
15. The method of claim 12, 13 or 14, wherein if the clamping sensor (322) fails to sense
the clamp head (310) positioned at a bottom dead point during a third preset time
after the controller sends control signals to the actuators for shrinking thereof,
the controller stops all operations of the automated experiment apparatus and generates
a fourth alarm (S642).
16. The method of any of claims 12 to 15, wherein the automated experiment apparatus includes
a pressure sensor (146) configured to measure an internal pressure of the pressure
vessel (200), and
wherein during the supplying, if the internal pressure measured by the pressure sensor
(146) reaches a pressure limit, the controller stops all operations of the automated
experiment apparatus and generates a fifth alarm (S342).
17. The method of any of claims 12 to 16, wherein the automated experiment apparatus includes
a temperature sensor (148) configured to measure an internal temperature of the pressure
vessel (200), and
wherein during the heating, if the internal temperature measured by the temperature
sensor (148) reaches a temperature limit, the controller stops all operations of the
automated experiment apparatus and generates a sixth alarm (S442).
18. The method of any of claims 12 to 17, wherein if the upper position sensor (142) fails
to sense the sample holding member (120) located at the upper position during a fourth
preset time after the controller sends a control signal to the lifter to move up the
sample holding member, the controller stops all operations of the automated experiment
apparatus and generates a seventh alarm (S742).
1. Automatisierte Versuchseinrichtung, umfassend:
ein Druckgefäß (200), das eine Öffnung aufweist, um eine Probenaufnahmekammer (220)
in demselben zu definieren, wobei das Druckgefäß einen Gefäßflansch (210) einschließt,
der eine kreisrunde Außenform mit einem Radius um eine Mittelachse des Druckgefäßes
aufweist;
ein Probenhalteelement (120), das dazu konfiguriert ist, eine Probe zu halten, die
in der Probenaufnahmekammer (220) untergebracht werden soll, wobei das Probenhalteelement
einen Halterflansch (122) einschließt, der eine kreisrunde Außenform desselben Radius
wie der Gefäßflansch (210) aufweist und dazu konfiguriert ist, Kontakt mit dem Gefäßflansch
herzustellen, um die Öffnung zu verschließen;
eine Erfassungseinheit (140), die dazu konfiguriert ist, mindestens eine aus einer
oberen Position und einer unteren Position des Probenhalteelements (120) zu erfassen;
eine Vielzahl von Klemmen (300), die dazu konfiguriert sind, luftdicht mit dem Halterflansch
(122) des Probenhalteelements (120) und dem Gefäßflansch (210) des Druckgefäßes (200)
einzugreifen, wobei jede aus der Vielzahl von Klemmen einen Klemmenkopf (310), der
eine Nut (312) aufweist, die dazu konfiguriert ist, mit dem Halterflansch und dem
Gefäßflansch einzugreifen, und einen Aktor (330) einschließt, der mit dem Klemmenkopf
verbunden ist;
einen Klemmsensor (322), der dazu konfiguriert ist, einen oberen Totpunkt des Klemmenkopfes
(310) zu erfassen, bei dem der Klemmenkopf (310) vom Aktor (330) vollständig herausgedrückt
ist, um luftdicht mit dem Halterflansch (122) einzugreifen;
eine Gastransfereinheit (130), die eine Gaszuführung (132) und eine Gasabführung (136)
umfasst, die mit dem Probenhalteelement (120) verbunden und dazu konfiguriert sind,
ein Gas in das Druckgefäß (200) zuzuführen oder aus demselben abzuführen;
eine Heizeinheit (230), die dazu konfiguriert ist, die Probenaufnahmekammer (220)
zu erhitzen;
einen Drucksensor (146), der dazu konfiguriert ist, einen Innendruck des Druckgefäßes
(200) zu messen;
eine Benutzerschnittstelle (106), die dazu konfiguriert ist, eine Eingabe von einem
Benutzer zu empfangen; und
eine Steuerung (400), die dazu konfiguriert ist, ein Eingangssignal von der Benutzerschnittstelle
(106) und ein Erfassungssignal von der Erfassungseinheit (140) zu empfangen, um in
Antwort auf das Eingangssignal und das Erfassungssignal den Aktor (330) jeder der
Klemmen (300) so zu steuern, dass der Klemmenkopf (310) dazu gebracht wird, eine Querbewegung
in einer radialen Richtung des Gefäßflansches (210) vorzunehmen, um mit dem Halterflansch
(122) und dem Gefäßflansch (210) einzugreifen, in Antwort auf ein Klemmsensorsignal,
das aus dem Klemmsensor (322) empfangen wird, die Gastransfereinheit (130) so zu steuern,
dass dem Druckgefäß (200) das Gas zugeführt wird, bis der Innendruck des Druckgefäßes
(200) einen vorbestimmten Reaktionsdruck, wie von einem Drucksensorsignal aus dem
Drucksensor (146) angezeigt, erreicht, in Antwort auf das Drucksensorsignal aus dem
Drucksensor (146) die Heizeinheit (230) so zu steuern, dass die Probenaufnahmekammer
(220) erhitzt wird, und die Gastransfereinheit (130) so zu steuern, dass das Gas aus
der Probenaufnahmekammer (220) abgeführt wird.
2. Einrichtung nach Anspruch 1, wobei die Steuerung (400) umfasst:
einen Prozessor (430),
einen Speicher (420), der mit dem Prozessor gekoppelt ist, und
eine Schnittstellenschaltung (410), die mit dem Prozessor gekoppelt ist, wobei die
Schnittstellenschaltung weiter mit der Benutzerschnittstelle (106) und der Erfassungseinheit
(140) gekoppelt ist, um das Eingangssignal und das Erfassungssignal von denselben
zu empfangen, wobei die Schnittstellenschaltung ebenfalls mit dem Klemmsensor (322),
um ein Sensorsignal von demselben zu empfangen, und dem Aktor (330) jeder der Klemmen
gekoppelt ist, um Steuersignale an die Aktoren zu senden, um Betriebsvorgänge der
Aktoren zu steuern.
3. Einrichtung nach Anspruch 2, weiter umfassend:
einen Heber (112);
einen beweglichen Rahmen (116), der mit dem Probenhalteelement (120) und dem Heber
(112) verbunden ist; und
eine Führung (114), die dazu konfiguriert ist, Bewegung des beweglichen Rahmens zu
führen,
wobei die Schnittstellenschaltung (410) dazu konfiguriert ist, ein Steuersignal an
den Heber (112) zu senden, um den beweglichen Rahmen (116) vertikal zu bewegen.
4. Einrichtung nach Anspruch 2 oder 3,
wobei die Schnittstellenschaltung (410) dazu konfiguriert ist, ein Steuersignal an
die Gaszuführung zu senden, um der Probenaufnahmekammer das Gas zuzuführen, und
wobei die Schnittstellenschaltung (410) dazu konfiguriert ist, ein Steuersignal an
die Gasabführung zu senden, um das Gas aus der Probenaufnahmekammer abzuführen.
5. Einrichtung nach Anspruch 2, 3 oder 4, wobei die Erfassungseinheit (140) einen oberen
Positionssensor (142), der dazu konfiguriert ist, zu erfassen, ob sich das Probenhalteelement
(120) an der oberen Position befindet, und einen unteren Positionssensor (144) umfasst,
der dazu konfiguriert ist, zu erfassen, ob sich das Probenhalteelement an der unteren
Position befindet,
wobei der obere Positionssensor (142) mit der Sensorsignal-Empfangseinheit (414) gekoppelt
und dazu konfiguriert ist, ein Erfassungssignal desbezüglich, ob sich das Probenhalteelement
an der oberen Position befindet, an die Sensorsignal-Empfangseinheit zu senden, und
wobei der untere Positionssensor (144) mit der Sensorsignal-Empfangseinheit (414)
gekoppelt und dazu konfiguriert ist, ein Erfassungssignal desbezüglich, ob sich das
Probenhalteelement an der unteren Position befindet, an die Sensorsignal-Empfangseinheit
zu senden.
6. Einrichtung nach einem der Ansprüche 2 bis 5, wobei die Steuerung (400) dazu konfiguriert
ist, einen Reaktionsprozess automatisch unter einer vorbestimmten Temperatur und einem
vorbestimmten Druck auszuführen, wenn das Probenhalteelement (120) luftdicht am Druckgefäß
(200) befestigt ist.
7. Einrichtung nach einem vorstehenden Anspruch, wobei der Halterflansch (122) und der
Gefäßflansch (210) eine Ringform aufweisen, und die Nut (312) einen C-artigen vertikalen
Querschnitt aufweist.
8. Einrichtung nach einem vorstehenden Anspruch, wobei ein vertikaler Querschnitt der
Nut (312) von einer vertikalen Fläche (312b) und zwei Neigungsflächen (312a) definiert
wird, die so gebildet sind, dass sie sich jeweils von oberen und unteren Enden der
vertikalen Fläche (312b) erstrecken.
9. Einrichtung nach einem vorstehenden Anspruch, weiter umfassend:
ein Gehäuse (100), in dem das Druckgefäß (200) bereitgestellt ist; und
ein Gassteuermodul (500), das abnehmbar im Gehäuse untergebracht ist,
wobei das Gassteuermodul (500) umfasst:
eine Grundplatte (502), die Rohre zum Zuführen des Gases zu, oder Abführen des Gases
aus dem Druckgefäß (200) trägt, wobei die Grundplatte (502) abnehmbar am Gehäuse (100)
untergebracht ist;
einen Verbindungsblock (510), der auf einer Seite der Grundplatte angebracht ist;
ein Gaseingangsventil (520), das auf der Grundplatte bereitgestellt ist, um eine Gaszuführleitung
(134) zum Zuführen des Gases zum Druckgefäß zu öffnen oder zu schließen; und
ein Gasausgangsventil (530), das auf der Grundplatte bereitgestellt ist, um eine Gasabführleitung
(138) zum Abführen des Gases aus dem Druckgefäß zu öffnen oder zu schließen.
10. Einrichtung nach Anspruch 9, wobei der Verbindungsblock (510) in eine Verbindungsnut
(102) eingesetzt ist, die an einer Kante einer Wand des Gehäuses (100) vertieft ist,
wobei der Verbindungsblock (510) eine Position der Grundplatte (502) bestimmt, wenn
das Gassteuermodul (500) im Gehäuse untergebracht ist.
11. Einrichtung nach Anspruch 9 oder 10, wobei das Gassteuermodul (500) weiter ein Entlastungsventil
(540) umfasst, das auf der Grundplatte (502) bereitgestellt ist und automatisch geöffnet
wird, wenn ein Druck im Druckgefäß (200) gleich oder höher als ein vorbestimmter Druck
ist,
wobei am Verbindungsblock (510) ein Notventil (514) bereitgestellt ist, das dazu konfiguriert
ist, manuell betätigt zu werden, und sich an einer Mitte der Gasabführleitung (138)
befindet, und
wobei die Gasabführleitung mindestens drei Zweige (532, 534, 536) im Gassteuermodul
einschließt, und
wobei das Notventil (514), das Gasausgangsventil (530) und das Entlastungsventil (540)
jeweils an jedem der drei Zweige bereitgestellt sind.
12. Automatisiertes Versuchsverfahren unter Verwendung einer automatisierten Versuchseinrichtung,
umfassend:
Bewegen eines Probenhalteelements (120) der automatisierten Versuchseinrichtung nach
unten, um einen Halterflansch (122) der automatisierten Versuchseinrichtung mit einem
Gefäßflansch (210) der automatisierten Versuchseinrichtung in Kontakt zu bringen,
indem in Antwort auf ein von einer Steuerung (400) der automatisierten Versuchseinrichtung
gesendetes Steuersignal ein Heber (112) angetrieben wird, wobei das Probenhalteelement
(120) dazu konfiguriert ist, eine Probe zu halten, die in einer Probenaufnahmekammer
(220) der automatisierten Versuchseinrichtung untergebracht werden soll;
Ineingriffbringen des Halterflansches (122) und des Gefäßflansches (210), um ein Probenhalteelement
(120) und ein Druckgefäß (200) der automatisierten Versuchseinrichtung luftdicht zu
befestigen, indem die Steuerung Steuersignale an Aktoren (330) der automatisierten
Versuchseinrichtung sendet, um Klemmenköpfe (310) von Klemmen (300), die in der automatisierten
Versuchseinrichtung eingeschlossen sind, quer zum Halterflansch (122) und dem Gefäßflansch
(210) hin zu bewegen;
Zuführen eines Gases zu einer Probenaufnahmekammer (220) der automatisierten Versuchseinrichtung,
bis der Innendruck des Druckgefäßes (200) einen vorbestimmten Reaktionsdruck, wie
von einem Drucksensorsignal aus einem Drucksensor (146) angezeigt, erreicht;
Erhitzen der Probenaufnahmekammer (220) nach dem Zuführen;
Abführen des Gases aus der Probenaufnahmekammer (220);
Lösen des Halterflansches (122) und des Gefäßflansches (210), indem die Steuerung
(400) Steuersignale an die Aktoren (330) sendet, um die Klemmenköpfe (310) quer vom
Halterflansch und dem Gefäßflansch weg zu bewegen; und
Bewegen des Probenhalteelements (120) nach oben, indem der Heber (112) in Antwort
auf das von der Steuerung gesendete Steuersignal angetrieben wird.
13. Verfahren nach Anspruch 12, wobei die automatisierte Versuchseinrichtung eine Erfassungseinheit
(140) umfasst, die einen oberen Positionssensor (142), der erfasst, ob sich das Probenhalteelement
(120) an einer oberen Position befindet, und einen unteren Positionssensor (144) einschließt,
der erfasst, ob sich das Probenhalteelement (120) an einer unteren Position befindet,
wobei, wenn es dem oberen Positionssensor (142) nicht gelingt, zu erfassen, dass sich
das Probenhalteelement an der oberen Position befindet, bevor das Probenhalteelement
beginnt, sich nach unten zu bewegen, die Steuerung alle Betriebsvorgänge der automatisierten
Versuchseinrichtung stoppt und einen ersten Alarm erzeugt (S122), und
wobei, wenn es dem unteren Positionssensor (144) während der ersten voreingestellten
Zeit, nachdem die Steuerung das Steuersignal an den Heber gesendet hat, um das Probenhalteelement
nach unten zu bewegen, nicht gelingt, zu erfassen, dass sich das Probenhalteelement
(120) an der unteren Position befindet, die Steuerung alle Betriebsvorgänge der automatisierten
Versuchseinrichtung stoppt und einen zweiten Alarm erzeugt (S162).
14. Verfahren nach Anspruch 12 oder 13, wobei jede der Klemmen (300) einen Klemmsensor
(322) einschließt, der eine Position des Klemmenkopfes (310) erfasst, und
wobei, wenn es mindestens einem der Klemmsensoren (322) nicht gelingt, während einer
zweiten voreingestellten Zeit, nachdem die Steuerung Steuersignale an die Aktoren
sendet, um dieselben auszustrecken, zu erfassen, dass der entsprechende Klemmenkopf
(310) an einem oberen Totpunkt positioniert ist, die Steuerung alle Betriebsvorgänge
der automatisierten Versuchseinrichtung stoppt und einen dritten Alarm erzeugt (S242).
15. Verfahren nach Anspruch 12, 13 oder 14, wobei, wenn es dem Klemmsensor (322) während
einer dritten voreingestellten Zeit, nachdem die Steuerung Steuersignale an die Aktoren
sendet, um dieselben zurückzuziehen, nicht gelingt, zu erfassen, dass der Klemmenkopf
(310) an einem unteren Totpunkt positioniert ist, die Steuerung alle Betriebsvorgänge
der automatisierten Versuchseinrichtung stoppt und einen vierten Alarm erzeugt (S642).
16. Verfahren nach einem der Ansprüche 12 bis 15, wobei die automatisierte Versuchseinrichtung
einen Drucksensor (146) einschließt, der dazu konfiguriert ist, einen Innendruck des
Druckgefäßes (200) zu messen, und
wobei, wenn während des Zuführens der vom Drucksensor (146) gemessene Innendruck eine
Druckgrenze erreicht, die Steuerung alle Betriebsvorgänge der automatisierten Versuchseinrichtung
stoppt und einen fünften Alarm erzeugt (S342).
17. Verfahren nach einem der Ansprüche 12 bis 16, wobei die automatisierte Versuchseinrichtung
einen Temperatursensor (148) einschließt, der dazu konfiguriert ist, eine Innentemperatur
des Druckgefäßes (200) zu messen, und
wobei, wenn während des Erhitzens die vom Temperatursensor (148) gemessene Innentemperatur
eine Temperaturgrenze erreicht, die Steuerung alle Betriebsvorgänge der automatisierten
Versuchseinrichtung stoppt und einen sechsten Alarm erzeugt (S442).
18. Verfahren nach einem der Ansprüche 12 bis 17, wobei, wenn es dem oberen Positionssensor
(142) während einer vierten voreingestellten Zeit, nachdem die Steuerung ein Steuersignal
an den Heber sendet, um das Probenhalteelement nach oben zu bewegen, nicht gelingt,
zu erfassen, dass sich das Probenhalteelement (120) an der oberen Position befindet,
die Steuerung alle Betriebsvorgänge der automatisierten Versuchseinrichtung stoppt
und einen siebten Alarm erzeugt (S742).
1. Appareil d'expérimentation automatisé, comprenant :
une cuve sous pression (200) présentant une ouverture pour définir une chambre de
réception d'échantillon (220) à l'intérieur de celle-ci, la cuve sous pression incluant
une bride de cuve (210) présentant une forme extérieure circulaire avec un rayon autour
d'un axe central de la cuve sous pression ;
un élément de support d'échantillon (120) configuré pour maintenir un échantillon
devant être logé dans la chambre de réception d'échantillon (220), l'élément de support
d'échantillon incluant une bride de support (122) présentant une forme extérieure
circulaire de même rayon que celui de la bride de cuve (210) et configuré pour entrer
en contact avec la bride de cuve pour fermer l'ouverture ;
une unité de détection (140) configurée pour détecter au moins l'une parmi une position
haute et une position basse de l'élément de support d'échantillon (120) ;
une pluralité de pinces (300) configurées pour mettre en prise de manière hermétique
la bride de support (122) de l'élément de support d'échantillon (120) et la bride
de cuve (210) de la cuve sous pression (200) dans lequel chacune de la pluralité de
pinces inclut une tête de pince (310) présentant une rainure (312) configurée pour
venir en prise avec la bride de support et la bride de cuve, et un actionneur (330)
raccordé à la tête de pince ;
un capteur de serrage (322) configuré pour détecter un point mort haut de la tête
de pince (310) au niveau duquel la tête de pince (310) est entièrement poussée vers
l'extérieur par l'actionneur (330) pour entrer en prise hermétiquement avec la bride
de support (122) ;
une unité de transfert de gaz (130) présentant un dispositif d'alimentation en gaz
(132) et d'un dispositif d'évacuation de gaz (136) raccordée à l'élément de support
d'échantillon (120) et configurée pour alimenter ou évacuer un gaz dans ou à partir
de la cuve sous pression (200) ;
une unité chauffante (230) configurée pour chauffer la chambre de réception d'échantillon
(220) ;
un capteur de pression (146) configuré pour mesurer une pression interne de la cuve
sous pression (200) ;
une interface utilisateur (106) configurée pour recevoir une saisie d'un utilisateur
; et
un dispositif de commande (400) configuré pour recevoir un signal d'entrée de l'interface
utilisateur (106) et un signal de détection de l'unité de détection (140) pour commander,
en réponse au signal d'entrée et au signal de détection, l'actionneur (330) de chacune
des pinces (300) pour amener la tête de pince (310) à réaliser un mouvement transversal
dans un sens radial de la bride de cuve (210) pour mettre en prise la bride de support
(122) et la bride de cuve (210), pour commander, en réponse à un signal du capteur
de serrage reçu du capteur de serrage (322), à l'unité de transfert de gaz (130) de
fournir le gaz dans la cuve sous pression (200) jusqu'à ce que la pression interne
de la cuve sous pression (200) atteigne une pression de réaction prédéfinie telle
qu'indiquée par un signal de capteur de pression du capteur de pression (146), pour
commander, en réponse au signal de capteur de pression du capteur de pression (146),
à l'unité chauffante (230) de chauffer la chambre de réception d'échantillon (220),
et pour commander à l'unité de transfert de gaz (130) d'évacuer le gaz de la chambre
de réception d'échantillon (220).
2. Appareil selon la revendication 1, dans lequel le dispositif de commande (400) comprend
:
un processeur (430),
une mémoire (420) couplée au processeur, et
un circuit d'interfaçage (410) couplé au processeur, le circuit d'interfaçage couplé
en outre à l'interface utilisateur (106) et à l'unité de détection (140) pour recevoir
le signal d'entrée et le signal de détection de ceux-ci, le circuit d'interfaçage
étant également couplé au capteur de serrage (322) pour recevoir un signal de capteur
de celui-ci, et l'actionneur (330) de chacune des pinces pour envoyer des signaux
de commande aux actionneurs pour commander des opérations des actionneurs.
3. Appareil selon la revendication 2, comprenant en outre :
un dispositif de levage (112) ;
un cadre mobile (116) raccordé à l'élément de support d'échantillon (120) et au dispositif
de levage (112) ; et
un guide (114) configuré pour guider le mouvement du cadre mobile,
dans lequel le circuit d'interfaçage (410) est configuré pour envoyer un signal de
commande au dispositif de levage (112) pour déplacer verticalement le cadre mobile
(116).
4. Appareil selon la revendication 2 ou 3,
dans lequel le circuit d'interfaçage (410) est configuré pour envoyer un signal de
commande au dispositif d'alimentation en gaz pour fournir le gaz à la chambre de réception
d'échantillon, et
dans lequel le circuit d'interfaçage (410) est configuré pour envoyer un signal de
commande au dispositif d'évacuation de gaz pour évacuer le gaz de la chambre de réception
d'échantillon.
5. Appareil selon la revendication 2, 3 ou 4, dans lequel l'unité de détection (140)
comprend un détecteur de position haute (142) configuré pour détecter si l'élément
de support d'échantillon (120) est situé en position haute et un détecteur de position
basse (144) configuré pour détecter si l'élément de support d'échantillon est situé
en position basse,
dans lequel le détecteur de position haute (142) est couplé à l'unité de réception
de signal du détecteur (414) et configuré pour envoyer un signal de détection indiquant
si l'élément de support d'échantillon est situé en position haute à l'unité de réception
de signal du détecteur, et
dans lequel le détecteur de position basse (144) est couplé à l'unité de réception
de signal du détecteur (414) et configuré pour envoyer un signal de détection indiquant
si l'élément de support d'échantillon est situé en position basse à l'unité de réception
de signal du détecteur.
6. Appareil selon l'une quelconque des revendications 2 à 5, dans lequel le dispositif
de commande (400) est configuré pour exécuter automatiquement un procédé de réaction
à une température prédéfinie et une pression prédéfinie lorsque l'élément de support
d'échantillon (120) est fixé hermétiquement à la cuve sous pression (200).
7. Appareil selon l'une quelconque des revendications précédentes, dans lequel la bride
de support (122) et la bride de cuve (210) présentent une forme annulaire, et la rainure
(312) présente une section transversale verticale en forme de C.
8. Appareil selon l'une quelconque des revendications précédentes, dans lequel une section
transversale verticale de la rainure (312) est définie par une surface verticale (312b)
et deux surfaces inclinées (312a) formées pour s'étendre à partir d'extrémités supérieures
et inférieures, respectivement, de la surface verticale (312b).
9. Appareil selon l'une quelconque des revendications précédentes, comprenant en outre
:
un boîtier (100) dans lequel la cuve sous pression (200) est prévue ; et
un module de commande de gaz (500) logé de manière amovible dans le boîtier,
dans lequel le module de commande de gaz (500) comprend :
une plaque de base (502) soutenant des tuyaux destinés à fournir le gaz à ou à évacuer
le gaz de la cuve sous pression (200), dans lequel la plaque de base (502) est logée
de manière amovible dans le boîtier (100) ;
un bloc de raccordement (510) fixé sur un côté de la plaque de base ;
une soupape d'admission de gaz (520) prévue sur la plaque de base pour ouvrir ou fermer
la conduite d'alimentation en gaz (134) destinée à fournir le gaz à la cuve sous pression
; et
une soupape de sortie de gaz (530) prévue sur la plaque de base pour ouvrir ou fermer
la conduite d'évacuation de gaz (138) destinée à évacuer le gaz de la cuve sous pression.
10. Appareil selon la revendication 9, dans lequel le bloc de raccordement (510) est introduit
dans une rainure de raccordement (102) en retrait sur un bord d'une paroi du boîtier
(100),
dans lequel le bloc de raccordement (510) détermine une position de la plaque de base
(502) lorsque le module de commande de gaz (500) est logé dans le boîtier.
11. Appareil selon la revendication 9 ou 10, dans lequel le module de commande de gaz
(500) comprend en outre une soupape de décharge (540) prévue sur la plaque de base
(502) et qui s'ouvre automatiquement lorsqu'une pression dans la cuve sous pression
(200) est supérieure ou égale à une pression prédéfinie,
dans lequel une soupape d'urgence (514) est prévue sur le bloc de raccordement (510),
configurée pour être manipulée manuellement, et située au milieu de la conduite d'évacuation
de gaz (138), et
dans lequel la conduite d'évacuation de gaz inclut au moins trois dérivations (532,
534, 536) dans le module de commande de gaz, et
dans lequel la soupape d'urgence (514), la soupape de sortie de gaz (530) et la soupape
de décharge (540) sont respectivement prévues sur chacune des trois dérivations.
12. Procédé d'expérimentation automatisé utilisant un appareil d'expérimentation automatisé,
comprenant :
le déplacement d'un élément de support d'échantillon (120) de l'appareil d'expérimentation
automatisé vers le bas pour mettre en contact une bride de support (122) de l'appareil
d'expérimentation automatisé avec une bride de cuve (210) de l'appareil d'expérimentation
automatisé en entraînant un dispositif de levage (112) en réponse à un signal de commande
envoyé par un dispositif de commande (400) de l'appareil d'expérimentation automatisé,
dans lequel l'élément de support d'échantillon (120) est configuré pour maintenir
un échantillon devant être logé dans une chambre de réception d'échantillon (220)
de l'appareil d'expérimentation automatisé ;
la mise en prise de la bride de support (122) et de la bride de cuve (210) pour fixer
hermétiquement un élément de support d'échantillon (120) et une cuve sous pression
(200) de l'appareil d'expérimentation automatisé par le dispositif de commande envoyant
des signaux de commande aux actionneurs (330) de l'appareil d'expérimentation automatisé
pour déplacer les têtes de pince (310) des pinces (300) incluses dans l'appareil d'expérimentation
automatisé transversalement vers la bride de support (122) et la bride de cuve (210)
;
la fourniture d'un gaz à une chambre de réception d'échantillon (220) de l'appareil
d'expérimentation automatisé jusqu'à ce que la pression interne de la cuve sous pression
(200) atteigne une pression de réaction prédéfinie telle qu'indiquée par un signal
de capteur de pression d'un capteur de pression (146) ;
le chauffage de la chambre de réception d'échantillon (220) après la fourniture ;
l'évacuation du gaz de la chambre de réception d'échantillon (220) ;
la désolidarisation de la bride de support (122) et de la bride de cuve (210) par
le dispositif de commande (400) envoyant des signaux de commande aux actionneurs (330)
pour déplacer les têtes de pince (310) transversalement à distance de la bride de
support et de la bride de cuve ; et
le déplacement de l'élément de support d'échantillon (120) vers le haut en entraînant
le dispositif de levage (112) en réponse au signal de commande envoyé par le dispositif
de commande.
13. Procédé selon la revendication 12, dans lequel l'appareil d'expérimentation automatisé
comprend une unité de détection (140) incluant un détecteur de position haute (142)
détectant si l'élément de support d'échantillon (120) est situé dans une position
haute et un détecteur de position basse (144) détectant si l'élément de support d'échantillon
(120) est situé dans une position basse,
dans lequel si le détecteur de position haute (142) ne parvient pas à détecter si
l'élément de support d'échantillon est en position haute avant le début du déplacement
vers le bas de l'élément de support d'échantillon, le dispositif de commande arrête
toutes les opérations de l'appareil d'expérimentation automatisé et génère un premier
signal d'alarme (S122), et
dans lequel si le détecteur de position basse (144) ne parvient pas à détecter si
l'élément de support d'échantillon (120) est en position basse pendant la première
période de temps prédéfinie suivant l'envoi du signal de commande par le dispositif
de commande au dispositif de levage pour déplacer vers le bas l'élément de support
d'échantillon, le dispositif de commande arrête toutes les opérations de l'appareil
d'expérimentation automatisé et génère un deuxième signal d'alarme (S162).
14. Procédé selon la revendication 12 ou 13, dans lequel chacune des pinces (300) inclut
un capteur de serrage (322) détectant une position de la tête de pince (310), et
dans lequel si au moins l'un des capteurs de serrage (322) ne parvient pas à détecter
la tête de pince correspondante (310) positionnée à un point mort haut pendant une
deuxième période de temps prédéfinie suivant l'envoi de signaux de commande par le
dispositif de commande aux actionneurs pour s'étirer de celle-ci, le dispositif de
commande arrête toutes les opérations de l'appareil d'expérimentation automatisé et
génère un troisième signal d'alarme (S242).
15. Procédé selon la revendication 12, 13 ou 14, dans lequel si le capteur de serrage
(322) ne parvient pas à détecter la tête de pince (310) positionnée à un point mort
bas pendant une troisième période de temps prédéfinie suivant l'envoi de signaux de
commande par le dispositif de commande aux actionneurs pour se rétracter de celle-ci,
le dispositif de commande arrête toutes les opérations de l'appareil d'expérimentation
automatisé et génère un quatrième signal d'alarme (S642).
16. Procédé selon l'une quelconque des revendications 12 à 15, dans lequel l'appareil
d'expérimentation automatisé inclut un capteur de pression (146) configuré pour mesurer
une pression interne de la cuve sous pression (200), et
dans lequel pendant la fourniture, si la pression interne mesurée par le capteur de
pression (146) atteint une limite de pression, le dispositif de commande arrête toutes
les opérations de l'appareil d'expérimentation automatisé et génère un cinquième signal
d'alarme (S342).
17. Procédé selon l'une quelconque des revendications 12 à 16, dans lequel l'appareil
d'expérimentation automatisé inclut un capteur de pression (148) configuré pour mesurer
une température interne de la cuve sous pression (200), et
dans lequel pendant la phase de chauffage, si la température interne mesurée par le
capteur de température (148) atteint une limite de température, le dispositif de commande
arrête toutes les opérations de l'appareil d'expérimentation automatisé et génère
un sixième signal d'alarme (S442).
18. Procédé selon l'une quelconque des revendications 12 à 17, dans lequel si le détecteur
de position haute (142) ne parvient pas à détecter si l'élément de support d'échantillon
(120) est situé en position haute pendant la quatrième période de temps prédéfinie
suivant l'envoi d'un signal de commande par le dispositif de commande au dispositif
de levage pour déplacer vers le haut l'élément de support d'échantillon, le dispositif
de commande arrête toutes les opérations de l'appareil d'expérimentation automatisé
et génère un septième signal d'alarme (S742).